Initial series

Because maternal antibodies passively protect newborn animals, it is not usually possible to vaccinate very young animals successfully. If protection is deemed necessary at this stage, the mother may be vaccinated during pregnancy. Maternal vaccinations should be timed so that peak antibody levels are achieved at the time of colostrum formation. Once an animal is born, successful active immunization is effective only after maternal antibodies have waned. Animals should be revaccinated 12 months later or at 1 year of age. It is unclear whether maternal antibodies can always block antibody responses to intranasal vaccines. Despite high levels of circulating maternal antibodies, maternal interference does not always occur and nasal antibody production is often unimpaired.

The timing of initial vaccinations may also be determined by disease epidemiology. Some diseases are seasonal, and vaccines may be given before outbreaks are anticipated. Examples of these include the vaccine against the lungworm, Dictyocaulus viviparus, given in early summer just before the anticipated lungworm season; the vaccine against anthrax given in spring; and the vaccine against Clostridium chauvoei given to sheep before turning them out to pasture. Bluetongue of lambs is spread by midges and is thus a disease of midsummer and early fall. Vaccination in spring will therefore protect lambs during the susceptible period. Similar considerations apply to mosquito-borne/wet season diseases.

Vaccination intervals

When deciding on the optimal interval between the first immunization and the booster shot it is important to consider how B cells and T cells differentiate. These cells respond rapidly to antigen and generate effector cells or plasma cells. Once this phase is over, most effector cells die while the survivors differentiate into memory cells. Memory T cells may take several weeks after the primary immune response to reach maximal numbers. Only when this memory phase develops can a significant secondary response be induced. As a general rule it is better to wait for as long as possible between prime and boost. Boosting too soon may well result in suboptimal secondary responses. (But boosting too late may open a window of vulnerability). Excessive boosting of mice appears to drive T cells toward terminal differentiation and deplete the population of central memory cells. Similar considerations apply to B cell responses. They need time to develop memory cells and premature boosting runs the risk of generating suboptimal memory. Computer modeling suggests that an interval of several weeks is necessary to obtain optimal secondary responses. In children, 4 to 8 weeks is considered to be the minimal interval between the first two doses by the Centers for Disease Control and Prevention (CDC), whereas six months is the recommended interval between the second and third vaccine doses. Studies on revaccination with Clostridial vaccines in sheep also suggest that an interval of 8 weeks between vaccine doses is optimal. A study on boosting cattle with rabies vaccine suggested that the optimal response was obtained with a 180-day interval between vaccine doses.

Although experimental data suggest that vaccination intervals be somewhat longer than currently recommended, one must also remember that it is essential not to leave a window of susceptibility between vaccine doses. For practical purposes, it is generally recommended that in dogs and cats the minimal interval should be 2 to 3 weeks. For larger animals such as horses it is generally a minimum of 3 to 4 weeks. In general, the longer the interval between booster shots, the better it is for the induction of a maximal protective response. Decisions on vaccination frequency however must be at the discretion of the vaccinating veterinarian.

Revaccination

Revaccination schedules depend on the duration of effective protection. This in turn depends on specific antigen content, whether the vaccine consists of living or dead organisms, and its route of administration. In the past, relatively poor vaccines may have required frequent administration, perhaps as often as every six months, to maintain an acceptable level of immunity. Modern vaccines usually produce a long-lasting protection, especially in companion animals. Many require revaccination only every three or four years, whereas for others, immunity may persist for an animal’s lifetime. Even inactivated viral vaccines may protect individual animals against disease for many years. Unfortunately, the minimal duration of immunity has rarely been measured, until recently, and reliable figures are not available for many vaccines. Although serum antibodies can be monitored in vaccinated animals, tests have not been standardized, and there is no consensus regarding the interpretation of these antibody titers. Even animals that lack detectable antibodies may have significant cell-mediated resistance to disease. Nor is there much detailed information available regarding long-term immunity on mucosal surfaces. In general, immunity against feline panleukopenia, canine distemper, canine parvovirus, and canine adenovirus is considered to be relatively long lasting (>5 years). On the other hand, immunity to feline herpesvirus, feline calicivirus, and Chlamydia is believed to be relatively short. One problem in making these statements is the variability among individual animals and among different types and brands of vaccine. Thus recombinant canine distemper vaccines may induce shorter duration immunity than conventional, modified live vaccines. There may be a great difference between the shortest and longest duration of immunological memory within a group of animals. Duration of immunity studies are confounded by the fact that many older animals have increased innate resistance. Different vaccines within a category may differ significantly in their performance, and although all vaccines may induce immunity in the short term, it cannot be assumed that all confer long-term immunity. Manufacturers use different master seeds and different methods of antigen preparation. A significant difference exists between the minimal level of immunity required to protect most animals and the level of immunity required to ensure protection of all animals.

Annual revaccination was once the rule for most animal vaccines because this approach was administratively simple and had the advantage of ensuring that an animal was seen regularly by a veterinarian. It is clear, however, that modern vaccines such as those against canine distemper or feline herpesvirus induce protective immunity that can last for many years and that annual revaccination using these vaccines is excessive. A growing body of evidence now indicates that most modified live viral vaccines induce lifelong sterile immunity in dogs and cats. In contrast, immunity to bacteria is of much shorter duration and often may prevent disease but not infection. Old dogs and cats rarely die from vaccine-preventable disease, especially if they have been vaccinated as adults. In contrast, young animals die from such diseases, especially if not vaccinated or vaccinated prematurely.

Notwithstanding this discussion, animal owners should be made aware that protection against an infectious disease can only be maintained reliably when vaccines are used in accordance with the protocol approved by the vaccine-licensing authorities. The duration of immunity claimed by a vaccine manufacturer is the minimum duration of immunity that is supported by the data available at the time the vaccine license is approved. This must always be taken into account when discussing revaccination protocols with an owner.